DE19758111A1 - Process for atomizing melts using film-forming linear nozzles - Google Patents

Abstract

The invention relates to a method for producing fine powder preferably having a spherical habit by atomizing molten materials with gases. In order to economically manufacture fine, gas atomized powder in addition to avoiding standstill times caused by clogging due to impure molten materials and by freezing due to heat loss, the invention provides that the molten material (5) flows out of a molten material nozzle (4) with an essentially rectangular outflow cross-section (8) in the form of a film (6). Afterwards, the molten material, together with an atomizing gas, flows out of a linear Laval nozzle (3) through a firstly converging and then diverging gas nozzle (3) having an essentially rectangular cross-section, whereby the laminar accelerated gas flow stabilizes and simultaneously draws the molten film (6) in a converged part of the Laval nozzle (3) until the molten film (6) is evenly atomized over an entire length after passing through the narrowest cross-section (9).

Description

Gas atomization techniques are widely used industrially to produce metal powders. A wide variety of nozzle designs are used - a good overview can be found in AJ Yule and JJ Dunkley: "Atomization of Melts", Oxford, 1994, pp. 165-189 [1] - which all have in common that the atomizing gas under pressure is from a or several gas nozzles escapes and as a turbulent jet approaches the melt flowing out of a melt nozzle at an angle and atomizes it. The gas loses a large part of its energy on the way to the melt. The result at atomizing gas pressures up to approximately 35 bar is relatively coarse metal powder with average grain diameters d ₅₀ in the atomized state around 50 µm and above. The powders usually have a broad particle size distribution because the atomization pulse is subject to strong fluctuations due to the turbulence. Special high-pressure nozzles with operating pressures of up to 100 bar have been developed (for example, Ting et al .: "A novel high pressure gas atomizing nozzle for liquid metal atomization", Adv. Powder Metall. Particulate Mater. (1996) 1, p. 97-108 [2]), which can produce medium grain sizes of approx. 20 µm with very high gas consumption. Processes with turbulent gas flow are all not suitable for the direct production of fine powders with average grain diameters d ₅₀ to 10 µm.

One way of producing fine metal and ceramic powders (DE 33 11 343: A. Walz: "Process for producing fine metal powders and apparatus for carrying out the process" [3]) is the use of laminar gas flows in a concentric Laval nozzle with preheated atomizing gas. The melt nozzle is positioned so that it is in the convergent part of the Laval nozzle, that is, that the melt nozzle protrudes into the Laval nozzle. The flow in the upper part of the Laval nozzle is laminar. Compared to processes with turbulent gas flows, there are finer powders with a narrower grain size distribution with a comparatively lower specific gas consumption (see Fig. 2 in [4]). The specific gas consumption for the production of a steel powder with an average grain diameter of 10 µm is approximately 7-8 Nm ³ Ar / kg [4], corresponding to approximately 12.5 to 14.2 kg Ar / kg steel.

DE 35 33 964 (A. Walz: "Process and Device for producing fine powder in spherical form "[5]), in which the Atomizing gas into the radially symmetrical, heated gas funnel Laval nozzle is inserted, being from within this gas judge placed melt nozzle emerging metal by heat transfer through Radiation emitted by the heated guest judge is overheated or heated.

Finally, DE 37 37 130 (A. Walz: "Method and device for Manufacture of very fine powder "[6]) claims another process variant the vacuum created by the flowing gas in the Laval nozzle is used to suck melt from a separate melting device. Also this is a radially symmetrical nozzle system with inside the Laval nozzle placed melt nozzle.

From G. Schulz: "Laminar Sonic and Supersonic Gas Flow Atomization - The NANOVAL-Process, "Adv. Powder Metall. & Particulate Mater. (1996), 1, pp. 43-54 [4] it is also known that it is used to produce fine metal powder according to the above Patent family is necessary, the emerging from the radially symmetrical nozzle Keep mass flow small - 12 to 30 kg / h and nozzle are indicated Melt nozzle diameters of 1 mm or less - if fine powder should be manufactured.

In the aforementioned processes, the laminar gas flows for atomization use, there are serious disadvantages in technical and above all from an economic point of view: for example, the types used are design-related concentric or also radially symmetrical nozzle systems (melt nozzles diameter of 1 min or less) particularly susceptible to mechanical Blockages due to entrained foreign particles or gas bubbles. Because of the  unfavorable ratio of outer melt nozzle surface to Melt volumes occur with high heat losses, which leads to undesired freezing Can cause and then, like the mechanical blockages, one Termination of spraying and longer downtimes result. In addition, the production outputs indicated are low and the specific gas consumption high. In the production of fine powders determine production output and specific gas consumption entirely decisive is the manufacturing costs. There is therefore a need for one Atomization process that through low gas consumption and high production performance is marked.

The object of the present invention is therefore to provide a method for the production to provide fine, gas atomized powder that the above described There are no disadvantages, particularly with regard to economical mass production having. That means, metal, metal alloy, salt, salt mixture or Also polymer melts on an industrial scale, if possible, using gas atomization inexpensive, but especially with low gas consumption and high Melt throughput can be atomized finely and evenly. Furthermore, the Melt nozzle against mechanical blockage due to impure melting as well be largely stable against freezing.

This object is achieved by the melt nozzle with a rectangular or largely rectangular cross-section is formed, the Cross-sectional area adjusted so by changing the length of the rectangle can be that any melt flow rate can be achieved. Surprisingly, it succeeds primarily from the rectangular melt nozzle emerging melt film, which because of its large surface area under free Outflow would be unstable by introducing it into the accelerated gas flow convergent part of the here also rectangular or largely rectangular stabilized Laval nozzle. This makes such a good relationship reached from the outer melt nozzle surface to the melt volume that Blockages due to freezing can be excluded. Separate In the worst case, foreign particles in contaminated melts only influence  a small part of the cross section of the melt nozzle, but without the The atomization process comes to a standstill. Below the narrowest cross section of the Laval nozzle, the melt film with a high specific impulse is evenly atomized in a fine powder with a preferably spherical habit.

Drawing 1 shows the atomization principle according to the invention. A gas space ( 1 ) with high pressure is separated from a gas space ( 2 ) with low pressure by an initially converging and then diverging gas nozzle with a rectangular or largely rectangular cross section (∼ linear Laval nozzle). The ratio of the pressure above the Laval nozzle p ₁ and below the Laval nozzle p ₂ corresponds at least to the critical pressure ratio of the atomizing gas used, so that the gas reaches the speed of sound in the narrowest cross section of the Laval nozzle. The pressure ratio is preferably p ₁ / p ₂ <2, particularly preferably <10. The higher the atomizing gas pressure p ₁ , the finer the powder produced. The melt ( 5 ) flows out of the melt nozzle ( 4 ) with a rectangular or largely rectangular outlet cross section. The melt nozzle can be designed as a casting distributor or crucible. The melt of the material to be atomized is generated and made available using known process techniques. The outlet of the melt nozzle is positioned above the Laval nozzle and aligned parallel to it. As a result of the pressure difference, the atomizing gas flows from the gas space ( 1 ) into the gas space ( 2 ). In the convergent part of the Laval nozzle, the gas is accelerated in laminar flow up to the speed of sound in the narrowest cross section. The gas always flows at a higher speed than the melt, stabilizes the melt film ( 6 ), stretches and accelerates it. Below the narrowest cross-section, the thin melt film is finally atomized evenly over its entire length with a high specific impulse to form a fine particle jet ( 7 ) of melt droplets, which then give off their heat and solidify into a fine powder. This stable thin film ( 6 ) is the prerequisite for the production of particularly fine powders (d ₅₀ = approx. 10 µm).

The inventive method is characterized in that the Spray gas can be preheated, but the preheating is not  is a necessary prerequisite for the feasibility of the procedure. Preheating of the atomizing gas is preferably dispensed with, as a result of which on the one hand, the equipment expenditure is reduced and, on the other hand, energy is saved becomes. For the same reasons, the one emerging from the melt nozzle Melt is preferably not additionally heated by radiation, although this is it is possible.

If the substance to be atomized does not react with the atomizing gas, i.e. it is inert against the gas, form from the melt droplets under the influence spherical particles from the surface tension. The atomizer to be reacted All or part of the substance with the atomizing gas and thereby form Reaction products, these can cause the formation of the melt droplets Balls interfere with the formation of irregularly shaped powder particles. Is in the particle beam a substrate at a distance at which the particles at least are still partially liquid, is the direct production of one Semi-finished product (spray compacting) possible.

Both the process variant with a rectangular cross section of the melt and Laval nozzle according to claim 1 and the process variant with a largely rectangular cross section of the melt and Laval nozzle according to claim 2 are characterized in that the ratio of the two sides of the rectangle a _Sd (long side) and b _Sd (short side) of the outlet cross section of the melt nozzle is at least a _Sd / b _Sd <1, preferably <2, particularly preferably <10, that the length of the linear Laval nozzle in the narrowest cross section a _{Ld is} greater than the length of the melt nozzle a _Sd is that the ratio of the width of the Laval nozzle to the width of the melt nozzle b _Ld / b _{Sd is} <1 and <100, preferably <10 and that the melt flow rate is achieved by simply lengthening the long side of the melt nozzle a _Sd and correspondingly lengthening the long side of the Laval nozzle a _Ld can be adjusted by the same amount to the desired production output without changing the grain size of the powder changes or the specific gas consumption increases. A projection of the melt nozzle exit surface ( 1 ) onto the narrowest cross section of the Laval nozzle ( 2 ) is shown in drawing 2 for the method variant according to the invention with a largely rectangular cross section.

The ratio of the cross-sectional areas of the melt nozzle outlet to the narrowest The cross section of the Laval nozzle is always larger in linear systems than in radially symmetrical nozzles. Since the flow rates of gas and metal at otherwise same conditions proportional to the corresponding nozzle cross-sectional area there are generally lower specifics for linear systems Gas consumption. The saving increases with the length of the nozzle system.

Due to the proportionality of the melt nozzle cross-sectional area and metal Throughput can be adjusted by adjusting the nozzle length Easily adjust production output. The characteristic Properties of the metal powder such as grain size, width of the grain size distribution The grain shape remains unchanged, but the specific gas consumption decreases as described above.

Examples

The production of fine powders according to the invention, preferably with a spherical habit, is described in the following examples without being restrictive.

• 1. A solder melt Sn62Pb36Ag2 with a temperature of 400 ° C flows out of a graphite melt nozzle with a rectangular outlet cross section of 15 mm ² (length of 30 mm, diameter of 0.5 mm). The narrowest cross section of the Laval nozzle has a length of 33 min and a thickness of 3.0 mm. Nitrogen with an overpressure (above ambient pressure) of 20 bar is used as the atomizing gas. There is also nitrogen in the spray tower with an overpressure of 0.1 bar. The atomization takes place as follows:
  • - Melt throughput: 143 g / s = 8.6 kg / min = 516 kg / h
  • - Specific gas consumption: 2.8 kg N ₂ / kg metal
  • - average grain diameter: 9.0 µm.
• 2. A steel melt of the alloy 42 Cr Mo 4 (material no. 1.7225) with a temperature of 1750 ° G flows out of a zirconium dioxide melting nozzle with a largely rectangular outlet opening of 35 mm ² (length of 50 mm, diameter of 0.7 mm). The narrowest cross section of the Laval nozzle has a length of 55 mm and a thickness of 3.5 mm. Argon with an overpressure (above ambient pressure) of 30 bar is used as the atomizing gas. There is also nitrogen in the spray tower with an overpressure of 0.1 bar. The atomization takes place as follows:
  • - Melt throughput: 333 g / s = 20 kg / min = 1200 kg / h
  • - Specific gas consumption: 4.5 kg Ar / kg metal
  • - average grain diameter: 9.5 µm.
• 3. A silver melt with a temperature of 1060 ° C flows out of a graphite melt nozzle with a largely rectangular outlet cross section of 20 mm ² (length of 20 mm, diameter of 1.0 mm). The narrowest cross section of the Laval nozzle has a length of 24 mm and a thickness of 4.0 mm. Nitrogen with an overpressure (above ambient pressure) of 18 bar is used as the atomizing gas. There is also nitrogen in the spray tower with an overpressure of 0.1 bar. The atomization takes place as follows:
  • - Melt throughput: 233 g / s = 14 kg / min = 840 kg / h
  • - Specific gas consumption: 1.67 kg N ₂ / kg metal
  • - average grain diameter: 9.0 µm.
• 4. An aluminum melt with a temperature of 800 ° C flows out of an alumina melting nozzle (Al ₂ O ₃ ) with a largely rectangular exit cross section of 120 mm ² (length of 200 mm, diameter of 0.6 mm). The narrowest cross section of the Laval nozzle has a length of 205 mm and a thickness of 3.0 mm. A mixture of nitrogen and oxygen with an oxygen content of 1% and an overpressure (above ambient pressure) of 30 bar is used as the atomizing gas. In the spray tower there is also the nitrogen / oxygen mixture with an overpressure of 0.2 bar, whereby small portions of the oxygen react with the aluminum particles on the surface and form a thin, stable oxide skin. The atomization takes place as follows:
  • - Melt throughput: 785 g / s = 47.1 kg / min = 2826 kg / h
  • - Specific gas consumption: 5.9 kg N ₂ / kg metal
  • - Average grain diameter: 10.1 µm.
• 5. A potassium chloride melt with a temperature of 820 ° C flows out of a graphite melt nozzle with a largely rectangular outlet cross section of 30 mm ² (length of 30 mm, diameter of 1.0 mm). The narrowest cross section of the Laval nozzle has a length of 33 mm and a thickness of 3.5 mm. Air with an overpressure (above ambient pressure) of 20 bar is used as the atomizing gas. There is also air in the spray tower with an overpressure of 0.1 bar. The atomization takes place as follows:
  • - melt throughput: 220 g / s = 13.2 kg / min = 792 kg / h
  • - Specific gas consumption: 22.1 kg air / kg salt
  • - average grain diameter: 8.5 µm.
• 6. A polyethylene melt (LDPE) with a temperature of 175 ° C flows out of a stainless steel melt nozzle with a rectangular outlet cross section of 15 mm ² (length of 30 mm, diameter of 0.5 min). The narrowest cross section of the Laval nozzle has a length of 33 mm and a thickness of 3.0 mm. Nitrogen with an overpressure (above ambient pressure) of 10 bar is used as the atomizing gas. There is also nitrogen in the spray tower with an overpressure of 0.1 bar. The atomization takes place as follows:
  • - melt throughput: 20 g / s = 1.2 kg / min = 72 kg / h
  • - Specific gas consumption: 9.1 kg N ₂ / kg polymer
  • - average grain diameter: 20 µm.

literature

[1] AJ Yule and JJ Dunkley:
Atomization of melts,
Oxford, 1994, pp. 165-189.
[2] J. Ting, R. Terpstra, IE Anderson, RS Figliola. and L. Mi:
A novel high pressure gas atomizing nozzle for liquid metal atomization,
Adv. Powder metal. Particulate Mater. (1996) 1, pp. 97-108.
[3] A. Walz:
Process for the production of fine metal powders and device for carrying out the process
Patent DE 33 11 343, filing date: March 29, 1983.
[4] G. Schulz:
Laminar Sonic and Supersonic Gas Flow Atomization - The NANOVAL- Process,
Adv. Powder Metal: Particulate Mater. (1996), 1, pp. 43-54.
[5] A. Walz:
Method and device for producing fine powder in spherical form,
Patent DE 35 33 964, filing date: September 24, 1985.
[6] A. Walz:
Method and device for producing very fine powder,
Patent DE 37 37 130, filing date: November 2, 1987

Claims (14)

1. A method for atomizing melts with gases to fine powders with preferably spherical habit, characterized in that the melt flows out in the form of a film from a melt nozzle with a rectangular outlet cross section, then together with a atomizing gas through a first converging and then diverging laminar flowed through Gas nozzle with a rectangular cross-section (∼ linear Laval nozzle) occurs, whereby the laminar accelerated gas flow in the convergent part of the Laval nozzle stabilizes the melt film and at the same time stretches until the melt film is atomized evenly over its entire length after passing through the narrowest cross-section. 2. The method according to claim 1, characterized in that the Exit cross section of the melt and / or Laval nozzle, such is modified that the two short sides of the rectangle of the Nozzle cross section through half arcs with a diameter are replaced according to the length of the short sides (largely rectangular cross section). 3. The method according to claim 1 or 2, characterized in that the ratio of the two sides of the rectangle a _Sd (long side) and b _Sd (short side) of the outlet cross section of the melt nozzle at least a _Sd / b _Sd <1, preferably <2, particularly preferably Is <10. 4. The method according to one or more of claims 1-3, characterized in that the length of the linear Laval nozzle in the narrowest cross section a _{Ld is} greater than the length of the melt nozzle a _Sd . 5. The method according to one or more of claims 1-4, characterized in that the ratio of the width of the Laval nozzle to the width of the melt nozzle b _Ld / b _Sd <1 and <100, preferably <10. 6. The method according to one or more of claims 1-5, characterized in that the melt throughput can be adapted to the desired production output by the same amount by simply lengthening the long side of the melt nozzle a _Sd and correspondingly lengthening the long side of the Laval nozzle a _Ld without changing the grain size of the powder or increasing the specific gas consumption. 7. The method according to one or more of claims 16, characterized in that the ratio of the pressure above the Laval nozzle p ₁ and below the Laval nozzle p ₂ corresponds at least to the critical pressure ratio of the atomizing gas used, so that the gas in the narrowest cross section the Laval nozzle reaches the speed of sound. 8. The method according to one or more of claims 1-7, characterized in that the pressure ratio p ₁ / p _{2 is} preferably <2, particularly preferably <10. 9. The method according to one or more of claims 1-8, characterized characterized in that the atomizing gas can be preheated, but does not necessarily need to be preheated. 10. The method according to one or more of claims 1-9, characterized characterized in that the melt emerged from the melt nozzle can be heated by radiation, but not necessarily heated must become. 11. The method according to one or more of claims 1-10, characterized characterized in that the melt nozzle also atomizes contaminated melts can be.   12. The method according to one or more of claims 1-11, characterized characterized in that the melt to be atomized is a metal, a metal alloy, a salt or salt mixture, or a fusible one Plastic deals. 13. The method according to one or more of claims 1-12, characterized characterized in that the substance to be atomized is not mixed with the atomizing gas reacts, i.e. is inert to the gas. 14. The method according to one or more of claims 1-12, characterized characterized in that the substance to be atomized completely with the atomizing gas or partially responded.